WO2000014912A1 - Measuring method for communication device - Google Patents

Abstract

A measuring method for a communication device by which the cost is reduced and the measurement space is reduced. A CPU (13) instructs a signal generator (4) to output a measuring signal. The signal generator (4) outputs a measuring signal generated by modulating a predetermined audio signal according to the instruction. A reception processing section (11) carries out predetermined reception processings including a demodulating processing of the measuring signal and outputs the demodulated signal. A low-frequency analyzer (6) measures a characteristic of the demodulated signal outputted from the reception processing section (11) and outputs the results of the measurement to the CPU (13). The CPU (13) displays the results of the measurement on an LCD (12) and adjusts a characteristic of the reception processing section (11).

Description

 Description Measurement system for communication equipment Technical field

 The present invention relates to a measurement method for a communication device that performs various types of measurement on the communication device. Background art

 In radio broadcasting, a broadcast station transmits a signal obtained by modulating an audio signal using a modulation method such as AM or FM modulation. For this reason, the radio receiver outputs the original audio signal by demodulating the received signal according to the modulation method.However, the elements such as the transistor and the like constituting the tuner in the radio receiver are However, even if the elements have the same element constant, the characteristics vary, so that even if a tuner is configured using the same element, the characteristics of the entire tuner are not necessarily the same. For this reason, the demodulated audio signal may be distorted or the output level may be reduced.

 Therefore, in the manufacturing process of a radio receiver, generally, the distortion and output level of the audio signal demodulated by the radio receiver are measured, and the element constant is adjusted based on the measurement result.

 FIG. 7 is a diagram showing a conventional measurement system for measuring characteristics of a radio receiver. The measurement system 500 shown in the figure measures the distortion and output level of the signal demodulated by the radio receiver 502, and includes a signal generator 504, a low-frequency analyzer 506, and a personal computer. It comprises a computer 508 and a display device 510.

When the distortion and output level of the demodulated signal are measured by the radio receiver 502 using the measurement system 500, the radio receiver 502 and the signal generator are transmitted from the personal computer 508. Measurement condition data such as carrier frequency and modulation method is transmitted to 504. The signal generator 504 is a measurement signal obtained by modulating a predetermined audio signal in accordance with the measurement condition data output from the personal computer 508. Output a signal. On the other hand, the radio receiver 502 demodulates the measurement signal output from the signal generator 504 according to the measurement condition data output from the personal computer 508, and obtains the signal obtained by the demodulation. Is output to the low-frequency analyzer 506. The low-frequency analyzer 506 measures the distortion and output level of the demodulated signal, and outputs the measurement result to the personal computer 508. Personal Consumer — The evening 508 displays the measurement results output from the low-frequency analyzer 506 on the display device 5110 to notify the measurement operator.

 However, the conventional measurement system 500 described above must be provided with a personal computer 508 and a display device 510, which complicates the configuration, increases the cost, and secures an installation place. I had to. In addition, since a personal computer 508 must be connected to each radio receiver 502 for measurement, the man-hour of the manufacturing process including adjustment and inspection has been increased.

 Also, in mobile phones such as mobile phones, it is measured whether demodulation processing and modulation processing are performed correctly, and various adjustments are made based on the measurement results. FIG. 8 is a diagram showing a conventional measurement system for measuring characteristics of a mobile phone. As shown in the figure, the measurement system 550 measures the distortion and output level of the signal demodulated or modulated by the mobile phone 552, and includes a signal generator 554, a low-frequency analyzer 5 56, an audio frequency signal generator (AF generator) 558, a transmission analyzer 560, a personal computer 562, and a display device 564.

 When measuring the distortion and output level of the demodulated signal by the mobile telephone 552 using this measurement system 550, the same operation as the measurement system 550 shown in FIG. 7 is performed. .

When measuring the distortion and output level of the signal modulated by the mobile phone 552 using this measurement system 550, the measurement is performed from the personal computer 562 to the AF generator 558. An instruction to output an audio signal for use is issued, and measurement condition data such as a carrier frequency and a modulation method are transmitted to the mobile phone 552. The mobile phone 555 is a total output from the AF generator 558. The measurement audio signal is modulated, and the modulated signal is output to the transmission analyzer 560. The transmission analyzer 560 measures the distortion and output level of the signal after the modulation, and outputs the measurement result to the personal computer 562. Personal convenience — evening 562 displays the measurement results output from the transmission analyzer 560 on the display device 564 to notify the measurement operator.

 However, as in the case of the measurement system 500 shown in FIG. 7, it is necessary to provide a personal convenience device 562 and a display device 564, which raises the problem of increased costs and difficulty in securing an installation location. In addition, it caused the man-hours of the manufacturing process to increase.

Disclosure of the invention

 The present invention has been made in view of the above points, and an object of the present invention is to provide a measurement method of a communication device capable of reducing cost and measuring space. According to the measurement method, a communication device including a processing device performs demodulation processing on a predetermined measurement signal generated and output by a signal generator, and outputs a demodulated signal. The characteristic of the signal is measured and the measurement result is sent to the processing device. The processing device included in the communication device controls a series of measurement procedures and notifies the measurement result. As described above, since the processing device included in the communication device controls the measurement operation, there is no need to provide another processing device (for example, a personal computer) for controlling the measurement operation as in the related art. Therefore, the configuration of the entire measurement system can be simplified and the cost can be reduced. In addition, since it is not necessary to secure a place for installing another processing apparatus, measurement space can be reduced. In addition, since there is no need to connect another processing device to the communication device in the manufacturing process, the number of steps in the manufacturing process can be reduced. In particular, the communication device is equipped with a display device, and the processing device provides a predetermined display on this display device to notify the measurement result, so that the measurement operator can easily measure without having to separately connect a display device or the like. The result can be confirmed.

Further, it is preferable that the above-mentioned processing device performs a control operation corresponding to at least a part of the reception operation when the communication device is in a normal operation. In this case, Since the processing device originally provided in the communication device can be used for controlling the measurement operation, there is no need to newly provide a processing device for controlling the measurement operation, and further cost reduction can be achieved.

 Further, the above-described processing device includes a reception processing unit that receives a carrier having a predetermined reception frequency and demodulates and extracts a signal included in the carrier, and performs various settings related to the reception processing unit using the processing device. Is preferred. By setting the reception frequency and modulation method of the communication device by the processing device, various measurement signals are appropriately received and subjected to predetermined demodulation processing, and the characteristics of the demodulated signal are measured by the measurement device. A series of measurement control for measurement can be performed.

 In addition, according to the measurement method of the communication device of the present invention, the communication device including the processing device performs a modulation process on a predetermined measurement signal generated and output by the signal generator and outputs a modulated signal. Is used to measure the characteristics of the signal after modulation and send the measurement result to the processing device.The processing device included in the communication device controls a series of measurement procedures and reports the measurement result. . Similar to the above-described measurement method of the communication device that performs a predetermined reception operation, the processing device included in the communication device controls the measurement operation, so that another processing device is used to control the measurement operation as in the related art. No need to prepare. Therefore, the configuration of the entire measurement system can be simplified and the cost can be reduced. Also, since there is no need to secure a place for installing another processing apparatus, measurement space can be reduced. In addition, since there is no need to connect another processing device to the communication device in the manufacturing process, the number of steps in the manufacturing process can be reduced.

 In particular, the communication device is equipped with a display device, and the processing device provides a predetermined display on this display device to notify the measurement result, so that the measurement operator can easily measure without having to separately connect a display device or the like. The result can be confirmed.

In addition, it is preferable that the processing device described above performs a control operation corresponding to at least a part of the transmission operation when the communication device is in a normal operation. In this case, the processing device originally provided in the communication device can be used for controlling the measurement operation, so that there is no need to newly provide a processing device for controlling the measurement operation, further reducing costs. Becomes possible. The communication device described above preferably includes a transmission processing unit that transmits a carrier having a predetermined frequency by performing a modulation process, and it is preferable that the processing device performs various settings for the transmission processing unit. It is possible to perform a series of measurement control in which a predetermined modulation process is performed on various input measurement signals and the characteristics of the modulated signal are measured by a measurement device. BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is a diagram showing the overall configuration of the measurement system of the first embodiment,

 Figure 2 shows the configuration of the radio receiver,

 FIG. 3 is a flowchart showing the measurement procedure in the measurement system shown in FIG. 1, FIG. 4 is a diagram showing the overall configuration of the measurement system of the second embodiment,

 FIG. 5 is a diagram showing a configuration of a mobile phone,

 Fig. 6 is a flowchart showing the measurement procedure in the measurement system shown in Fig. 4. Fig. 7 is a diagram showing a conventional measurement system for measuring the characteristics of a signal demodulated by a radio receiver.

 FIG. 8 is a diagram showing a conventional measurement system for measuring the characteristics of a signal demodulated or modulated by a mobile phone. BEST MODE FOR CARRYING OUT THE INVENTION

 A measurement system for a communication device according to an embodiment to which the present invention is applied is characterized in that control when measuring characteristics of a signal demodulated or modulated by the communication device is performed by a processing device provided in the communication device. I do. Hereinafter, a measurement system according to an embodiment will be described with reference to the drawings.

 (First Embodiment)

FIG. 1 is a diagram illustrating an overall configuration of a measurement system according to the first embodiment. The measurement system 100 shown in the figure is for measuring the characteristics of the signal demodulated by the radio receiver 2, and includes a signal generator 4 that outputs a measurement signal obtained by modulating a predetermined audio signal. It comprises a low-frequency analyzer 6 as a measuring device for measuring the characteristics of the signal demodulated by the radio receiver 2. The radio receiver 2 sends measurement condition data necessary for performing the measurement related to its own transmission function to the signal generator 4, and generates and outputs a predetermined measurement signal in accordance with the contents of the measurement condition data. To the signal generator 4. The measurement condition data includes information such as a carrier frequency, a modulation method (AM modulation, FM modulation, and the like), a modulation degree, and the like. After that, the radio receiver 2 receives the measurement signal output from the signal generator 4, performs a predetermined demodulation process on the received measurement signal, and outputs the demodulated signal to the low-frequency analyzer 6. I do.

 When the radio receiver 2 receives the measurement result of the demodulated signal from the low-frequency analyzer 6, the radio receiver 2 displays the measurement result on a built-in liquid crystal display (LCD) and displays the measurement result on the built-in reception device. Adjust the characteristics of the processing unit. The configuration of the radio receiver 2 will be described later.

 The signal generator 4 generates a measurement signal by modulating a predetermined audio signal according to a carrier frequency, a modulation method, and the like included in the measurement condition data input from the radio receiver 2, and generates the measurement signal. Is output to the radio receiver 2.

 When a low-frequency signal in the audible band, which is a demodulated signal, is input from the radio receiver 2 to the low-frequency analyzer 6, the low-frequency analyzer 6 measures characteristics such as the output level and waveform distortion of the demodulated signal and measures To the radio receiver 2.

 FIG. 2 is a diagram showing a configuration of the radio receiver 2. As shown in the figure, the radio receiver 2 is configured to include a reception processing unit 11, LCD 12, CPU 13, program storage unit 14, and data storage unit 15.

 The reception processing unit 11 has, for example, a circuit configuration of a superheterodyne system, and performs high-frequency amplification processing, frequency conversion processing, intermediate frequency amplification processing, and detection processing on the measurement signal output from the signal generator 4. And outputs the demodulated signal. The reception processing unit 11 is configured to include, for example, a variable capacitance capacitor for adjusting characteristics. By changing the capacity of the variable capacitor, for example, the amplification degree in the high frequency amplification processing is changed, and the characteristics of the reception processing unit 11 are adjusted.

The LCD 12 displays the frequency of the broadcast being received and the current time during normal reception operation, but when measuring the characteristics of the demodulated signal, the measurement results output from the low-frequency analyzer 6 are used. Is displayed to notify the measurement operator of the contents. The CPU 13 controls the entire radio receiver 2. For example, the CPU 13 sets a reception frequency and a demodulation method of the reception processing unit 11 according to a user's channel selection instruction so as to perform control so that the selected channel can be received or use. The volume of the speaker (not shown) is adjusted according to the volume adjustment instruction of the user.

 When measuring the characteristics of the demodulated signal, the CPU 13 outputs measurement condition data to the signal generator 4 and instructs the signal generator 4 to output a measurement signal in accordance with the contents of the measurement condition data. Put out. In addition, the CPU 13 determines the reception frequency of the reception processing unit 11 according to the carrier frequency and the modulation method included in the measurement condition data so that the reception processing unit 11 can perform the reception processing of the measurement signal. Set the demodulation method. Further, when the measurement result of the demodulated signal is input from the low frequency analyzer 6, the CPU 13 displays the measurement result on the LCD 12, and displays the characteristic of the reception processing unit 11 based on the measurement result. To adjust.

 The program storage unit 14 stores programs for performing various processes by the CPU 13. For example, a reception program for receiving a predetermined broadcast wave using the radio receiver 2 and a measurement program for performing a predetermined measurement operation are stored. The data storage unit 14 stores the measurement condition data and the like. The above-described radio receiver 2 corresponds to a communication device to be measured, the low frequency analyzer 6 corresponds to a measuring device, the LCD 12 corresponds to a display device, and the CPU 13 corresponds to a processing device.

 The measurement system 100 of the present embodiment has such a configuration, and the operation will be described next. FIG. 3 is a flowchart showing a measurement procedure in the measurement system 100 shown in FIG.

 The CPU 13 controls the reception frequency and the demodulation method of the reception control unit 11 according to the carrier frequency and the modulation method included in the measurement condition data so that the reception processing unit 11 can perform the reception processing of the measurement signal. Set (Step 100).

 Next, the CPU 13 sends measurement condition data to the signal generator 4 and instructs to output a measurement signal in accordance with the contents of the measurement condition data (step 101). In accordance with this instruction, the signal generator 4 outputs a measurement signal obtained by modulating a predetermined audio signal to the reception processing unit 11 (Step 102).

Next, the reception processing unit 11 recovers the measurement signal output from the signal generator 4. Predetermined reception processing including the modulation processing is performed, and the demodulated signal is output to the low frequency analyzer 6 (step 103). The low-frequency analyzer 6 measures characteristics such as the output level and waveform distortion of the demodulated signal output from the reception processing unit 11, and outputs the measurement result to the CPU 13 (step 104).

 When the measurement result is sent from the low frequency analyzer 6, the CPU 13 displays the measurement result on the LCD 12 (step 105). Next, the CPU 13 adjusts the characteristics of the reception processing unit 11 based on the measurement result (step 106). Specifically, CPU 13 determines whether or not the output level of the demodulated signal is within a predetermined range, whether or not the output waveform is distorted, and the like, based on the measurement result. When the output level of the demodulated signal is out of the predetermined range or when the output waveform is distorted, the CPU 13 includes a variable capacitor for characteristic adjustment included in the reception processing unit 11. And adjust the characteristics of the reception processing unit 11.

 Thus, in the measurement system 100 of the present embodiment, the CPU 13 provided in the radio receiver 2 instructs the signal generator 4 to output a measurement signal and the measurement result output from the low-frequency analyzer 206. Display processing is performed, and the measurement result is displayed on the LCD 12. Therefore, unlike the conventional measurement system 500 shown in FIG. 7, there is no need to connect a personal computer 508 or a display device 510 to perform measurement, and cost and space for measurement can be reduced. Can be. In addition, since there is no need for a step of connecting the personal computer 508 and the display device 510, the number of steps in the manufacturing process can be reduced. In addition, since the CPU 13 adjusts the characteristics of the reception processing unit 11 based on the measurement result output from the low-frequency analyzer 6, the characteristics of the reception processing unit 11 can be adjusted without human intervention. It can be adjusted.

 (Second embodiment)

Next, a measurement system according to a second embodiment of the present invention will be described. FIG. 4 is a diagram illustrating an overall configuration of a measurement system according to the second embodiment. The mobile phone 202 shown in the figure receives the carrier wave of a predetermined frequency (for example, 800 MHz band or 1.5 GHz) transmitted from the base station and performs demodulation processing to output the voice of the other party. Or the caller's voice collected by the built-in microphone (not shown). The voice signal is modulated and a carrier having a predetermined frequency is transmitted to the base station. The measurement system 200 is for measuring the characteristics of a signal (voice signal) demodulated by the mobile phone 202 and a modulated signal (carrier signal), and has a predetermined audio. A signal generator 204 that modulates the signal and outputs a measurement signal corresponding to the receiving operation of the mobile phone 202, and a measuring device that measures the characteristics of the signal demodulated by the mobile phone 202 A low-frequency analyzer 206, an audio frequency signal generator (AF generator) 208 that outputs a predetermined audio signal as a measurement signal corresponding to the transmission operation of the mobile phone 202, and a mobile unit It comprises a transmission analyzer 210 as a measuring device for measuring the characteristics of the signal modulated by the telephone set 202.

 The mobile phone 202 performs the following operation separately from the above-described normal call operation when measuring the demodulated signal or the modulated signal. Specifically, the mobile phone 202 sends to the signal generator 204 the measurement condition data necessary for performing the measurement related to its own reception function, and the mobile phone 202 determines the measurement condition data in accordance with the contents of the measurement condition data. The signal generator 204 is instructed to generate and output the measurement signal of the above. The measurement condition data includes, for example, information such as a carrier frequency and a modulation method of a radio wave transmitted from the base station and received by the mobile phone 202. Thereafter, mobile phone 202 receives the measurement signal output from signal generator 204, performs predetermined demodulation processing on the received measurement signal, and converts the demodulated signal to a low-frequency signal. Output to analyzer 206.

 In addition, the mobile phone 202 sends the measurement condition data necessary for performing the measurement relating to its own transmission function to the AF generator 208, and performs predetermined measurement according to the contents of the measurement condition data. Instruct the AF generator 208 to generate and output a signal. The measurement condition data includes, for example, information such as the frequency and amplitude level of an audio signal as a measurement signal input from the AF generator 208 to the mobile phone 202. Thereafter, mobile phone 202 performs a predetermined modulation process on the audio signal input from AF generator 208, and outputs the modulated signal to transmission analyzer 210.

In addition, the mobile telephone 202 is a low-frequency analyzer 206 or a transmission analyzer 210. When the measurement result is input from 0, the measurement result is displayed on the built-in liquid crystal display (LCD) and the characteristics of the built-in reception processing unit and transmission processing unit are adjusted. The configuration will be described later.

 The signal generator 204 generates a measurement signal by modulating a predetermined audio signal in accordance with the measurement condition data relating to the reception function input from the mobile phone 202, and generates the measurement signal. Output to telephone 202. When a low-frequency signal in the audible band, which is a demodulated signal, is input from the mobile phone 202, the low-frequency analyzer 206 measures characteristics such as the output level and waveform distortion of the demodulated signal. And outputs the measurement result to the mobile phone 202.

 The AF generator 208 generates an audio signal as a measurement signal in accordance with the measurement condition data relating to the transmission function input from the mobile phone 202 and outputs it to the mobile phone 202. When a carrier signal of a predetermined frequency, which is a signal after modulation, is input from the mobile phone 202, the transmission analyzer 210 measures characteristics such as the output level and waveform distortion of the signal after modulation. The measurement result is output to the mobile phone 202.

 FIG. 5 is a diagram showing a configuration of the mobile phone 202. As shown in FIG. As shown in the figure, the mobile phone 202 includes a reception processing unit 211, a transmission processing unit 212, an LCD 211 CPU 214, a program storage unit 215, and a data storage unit 211. 6 is included.

 The reception processing unit 211 has, for example, a circuit configuration of a super-heterodyne system, and performs high-frequency amplification processing, frequency conversion processing, and high-frequency measurement signals output from the signal generator 204. Performs intermediate frequency amplification processing, detection processing, etc., and outputs the demodulated signal. The transmission processing unit 212 performs predetermined modulation processing such as FM modulation on the low-frequency audio signal output from the AF generator 208, and outputs a modulated signal. The reception processing unit 211 and the transmission processing unit 212 include, for example, a variable capacitance capacitor for adjusting characteristics. By changing the capacity of the variable capacitor, the characteristics of the reception processing unit 211 and the transmission processing unit 212 are adjusted.

The LCD 212 normally displays the telephone number of the other party, but when measuring the characteristics of the demodulated signal and the modulated signal, the low-frequency analyzer 206 and the transmission analyzer are used. The measurement result output from the user 210 is displayed, and the contents are notified to the measurement operator.

 The CPU 214 controls the entire mobile phone 202. For example, the CPU 214 controls the reception processing unit 211 and the transmission processing unit 212 during a call and performs registration of a telephone number.

 When performing measurement relating to its own reception function, the CPU 214 outputs necessary measurement condition data to the signal generator 204 and the measurement output from the signal generator 204. The reception frequency, demodulation method, and the like of the reception processing unit 211 are set so that predetermined reception processing is performed on the reception signal by the reception processing unit 211. In addition, when the measurement result of the demodulated signal is input from the low-frequency analyzer 206, the CPU 214 displays the measurement result on the LCD 211, or based on the measurement result. Then, the characteristics of the reception processing unit 211 are adjusted.

 In addition, when performing measurement relating to its own transmission function, the CPU 214 outputs necessary measurement condition data to the AF generator 208 and the measurement data output from the AF generator 208. The transmission frequency and the like of the transmission processing unit 212 are set so that the transmission processing unit 212 performs predetermined transmission processing on the signal. Further, when the measurement result of the modulated signal is input from the transmission analyzer 210, the CPU 216 displays the measurement result on the LCD 213 or performs a transmission process based on the measurement result. Adjust the characteristics of the control unit 2 1 2.

 The program storage unit 215 stores programs for performing various processes by the CPU 214. For example, a normal operation program for making a call using the mobile phone 202 and a measurement program for performing a predetermined measurement operation are stored. The data storage unit 2 16 stores various measurement condition data, etc. c The above-mentioned mobile phone 202 is used as a communication device to be measured, the AF generator 208 is used as a signal generator, the transmission analyzer 210 corresponds to the measuring device, LCD213 corresponds to the display device, and CPU214 corresponds to the processing device.

The measuring system 200 of the communication device of the present embodiment has such a configuration, and the operation thereof will be described next. FIG. 6 is a flowchart showing a measurement procedure in the measurement system 200 shown in FIG. The operations in steps 200 to 206 are the same as the operations in steps 100 to 106 shown in FIG. 3 in the first embodiment described above. That is, the CPU 214 sets the reception frequency and the demodulation method of the reception control unit 211 in order to perform the reception processing of the measurement signal input from the signal generator 204 (Step 200).

 Next, the CPU 214 sends measurement condition data to the signal generator 204, and instructs to output a measurement signal in accordance with the contents of the measurement condition data (step 201). In accordance with the instruction, the signal generator 204 outputs a measurement signal obtained by modulating a predetermined audio signal to the reception processing unit 211 (step 202). Next, reception processing section 211 performs predetermined reception processing including demodulation processing on the measurement signal output from signal generator 204, and outputs the demodulated signal to low-frequency analyzer 206. (Step 203). The low frequency analyzer 206 measures the characteristics of the demodulated signal output from the reception processing unit 211 and outputs the measurement result to the CPU 214 (step 204). When the measurement result is sent from the low-frequency analyzer 206, the CPU 2 14 displays the measurement result on the LCD 213 (step 205), and based on the measurement result, determines the characteristics of the reception processing unit 211. Is adjusted (step 206).

 Next, the CPU 214 sets the transmission frequency of the transmission processing unit 212 to perform transmission processing on the audio signal input from the AF generator 208 (Step 207), and thereafter, sets the AF frequency. The measurement condition data is sent to the device 208, and an instruction is issued to output a measurement signal (audio signal) in accordance with the contents of the measurement condition data (step 208). The AF generator 208 outputs a predetermined audio signal to the transmission processing unit 212 in accordance with the instruction (step 209). The transmission processing unit 212 performs a predetermined transmission process including a modulation process on the audio signal output from the AF generator 208, and outputs the modulated signal to the transmission analyzer 210 (Step 21). 0).

The transmission analyzer 210 measures the characteristics of the modulated signal output from the transmission processing unit 212, and outputs the measurement result to the CPU 214 (step 211). When the measurement result is sent from the transmission analyzer 210, the CPU 214 displays the measurement result on the LCD 212 (step 2122), and transmits based on the measurement result. The characteristics of the processing unit 2 12 are adjusted (step 2 13).

As described above, in the measurement system 200 of the present embodiment, the measurement signal to the signal generator 204 and the AF generator 208 is controlled by the CPU 214 provided in the mobile phone 202. And the display processing of the measurement result output from the low frequency analyzer 206 or the transmission analyzer 210 is performed, and the measurement result is displayed on the LCD 212. Therefore, there is no need to connect a personal computer 562 or a display device 564 to perform measurement as in the conventional communication device measurement system 550 shown in FIG. 8, which reduces cost and reduces measurement. Space can be reduced. Moreover, since there is no need for processes that connect the personal computer 5 6 2 and display device 5 6 4, _c it is possible to reduce the man-hour of the manufacturing process In addition, the CPU 2 1 4, the low-frequency analyzer 2 0 The processing for adjusting the characteristics of the reception processing unit 211 based on the measurement results output from the transmission processing unit 211 is performed, and the characteristics of the transmission processing unit 212 based on the measurement results output from the transmission analyzer 210 are performed. Since the adjustment processing is performed, it is possible to adjust the characteristics of the reception processing unit 211 and the transmission processing unit 212 without manual intervention.

 Note that the present invention is not limited to the above embodiment, and various modifications can be made within the scope of the present invention. For example, in the above-described embodiment, the storage devices used for the program storage units 14 and 2 15 and the data storage units 15 and 2 16 are not limited, but an EEPROM (Electrically Erasable and Programmable ROM) In the case of using, it is possible to rewrite programs and measurement condition data. Therefore, it is possible to easily add or change the processing performed by the CPUs 13 and 2 14.

Further, in the above-described first embodiment, another receiver (for example, a television receiver) using the radio receiver 2 may be used as the communication device. Further, in the above-described second embodiment, the mobile phone 202 is used as the communication device, but another transceiver (for example, a transceiver) may be used. In the first embodiment described above, a communication device having only a reception function has been described, and in the second embodiment described above, a communication device having both a reception function and a transmission function has been described. The present invention may be applied to a communication device. Further, in the above-described embodiment, the measurement result is notified to the measurement worker by displaying the measurement result on the LCDs 12 and 21, but the measurement result is notified by outputting a sound from a speaker, an earphone, or the like. You may. Industrial applicability

As described above, according to the present invention, the processing device included in the communication device controls the measurement procedure for the signal after demodulation or the signal after modulation and notifies the measurement result. It is not necessary to connect another processing device for measurement control, so that the overall configuration can be simplified and the cost can be reduced. In addition, since it is not necessary to secure a place for installing other processing equipment, measurement space can be _reduced.c Further, since there is no need to connect other processing equipment to a communication device in the manufacturing process, It is also possible to reduce the number of steps in the manufacturing process.

Claims

The scope of the claims  1. a signal generator for generating and outputting a predetermined measurement signal;  A communication device that includes a processing device, performs a predetermined reception operation, performs a predetermined demodulation process on the measurement signal output from the signal generator, and outputs a demodulated signal; ,  A measuring device for sending a measurement result obtained by measuring characteristics of the demodulated signal output from the communication device to the processing device;  A measurement method for a communication device, comprising: controlling a series of measurement procedures by the processing device and notifying the measurement result sent from the measurement device.  2. The communication device includes a display device,  2. The communication system measurement method according to claim 1, wherein the processing device notifies the measurement result by performing a predetermined display on the display device. 3. The measurement method for a communication device according to claim 1, wherein the processing device performs a control operation corresponding to at least a part of the reception operation during a normal operation of the communication device.  4. The communication device receives a carrier having a predetermined reception frequency and includes a reception processing unit that demodulates and extracts a signal included in the carrier.  2. The measurement method for a communication device according to claim 1, wherein the processing device performs various setting processes required when the predetermined reception operation is performed by the reception processing unit.  5. The measurement method for a communication device according to claim 1, wherein the processing device is configured by a CPU that controls the measurement procedure by executing a predetermined measurement program.  6. A signal generator for generating and outputting a predetermined measurement signal;  A communication device that includes a processing device, performs a predetermined transmission operation, performs a predetermined modulation process on the measurement signal output from the signal generator, and outputs a modulated signal; , It is obtained by measuring the characteristics of the modulated signal output from the communication device. A measurement device for sending a measurement result to the processing device,  A measurement method for a communication device, comprising: controlling a series of measurement procedures by the processing device and notifying the measurement result sent from the measurement device.  7. The communication device includes a display device,  7. The communication system measurement method according to claim 6, wherein the processing device notifies the measurement result by performing a predetermined display on the display device. 8. The measurement method for a communication device according to claim 6, wherein the processing device performs a control operation corresponding to at least a part of the transmission operation during a normal operation of the communication device.  9. The communication device includes a transmission processing unit that transmits a carrier having a predetermined frequency by performing the predetermined modulation process,  7. The measurement method for a communication device according to claim 6, wherein the processing device performs various setting processes required when the predetermined transmission operation is performed by the transmission processing unit.  10. The measurement method for a communication device according to claim 6, wherein the processing device is configured by a CPU that controls the measurement procedure by executing a predetermined measurement program.